R 12013(ssc-411)-soil moisture constants,soil-water movement & infiltration
Soil Moisture Constants and Physical Properties of Selected Soils … · 2008-01-03 · Soil...
Transcript of Soil Moisture Constants and Physical Properties of Selected Soils … · 2008-01-03 · Soil...
Soil Moisture Constants and Physical Properties
of Selected Soils in Hawaii Teruo Yamamoto
U S. FOREST SERVICE RESEARCH PAPER PSW-P2 1963
Pac i f i c Sou thwes t Fo re s t and Range Expe r imen t S ta t ion - Be rk e l ey , Ca l i fo rn i a Forest Service - U. S. Department of Agriculture
The Author
Teruo Yamamoto is a geologist with the Pacific Southwest Sta-tion's watershed management research project in Honolulu, Hawaii. He was graduated from the University of Kansas City, Mo., and obtained a master's degree from Indiana University, Bloomington. He joined the Forest Service in 1957 as a geologist at the Southern Forest Experiment Station in Vicksburg, Miss., and was trans-ferred to Hawaii in 1959.
NOTICE: A uniform system of naming report series has been adopted for U. S. Forest Service Experiment Stations. Beginning January 1, 1963, research documents published by the Forest Serv-ice will be in one of these three series:
1. A numbered series, U.S. Forest Service Re-search Papers.
2. A numbered series, U.S. Forest Service Re-search Notes.
3. A numbered series, U.S. Forest Service Re-source Bulletins.
The publishing unit will be identified by letters before the number, and the numbers will be con-secutive in the order of publication dates. For example, this Station's first Research Paper in 1963 is designated U.S. Forest Service Research Paper PSW-P1.
Contents
Page
Introduction ............................................................................................................... ...1
Methods and Procedures ...............................................................................................1
Soil Properties ........................................................................................................... ...2
Texture and Structure ........................................................................................... ...2
Bulk Density ...........................................................................................................3
Soil Consistency . .................................................................................................. ...4
Organic Matter, pH, Specific Gravity ......................................................................5
Soil Moisture Constants and Land Use .........................................................................6
Summary ......................................................................................................................6
Literature Cited ............................................................................................................7
Appendix ......................................................................................................................9
The nature of soils influences and often deter-mines the use of land. Information on the physical characteristics of soils is needed as a guide to managing land for water production and other uses. In 1961 a detailed study was made of the strength and soil moisture characteristics of 25 soil types in Hawaii.1 Samples were obtained from the surface to the 12-inch depth at 34 sites on the islands of Hawaii, Kauai, and Oahu. These soils represent 10 great soil groups commonly found in the State of Hawaii.
Analyses were made of the differences in sur-face properties of fine-textured soils found under forest cover, in cultivated areas, in pastures, and in idle grassland. These studies provided data on soil texture, Atterberg limits, bulk density, organic matter content, specific gravity, pH, and soil mois-ture constants. This paper reports the results of these analyses.
Methods and Procedures
At each sampling site, we dug two to four pits, each about 2 feet deep. The exposed profile was described by- a soil scientist of the U.S. Soil Con-servation Service. Bulk samples composited from three locations within a 21- by 36-foot plot were taken from the 0- to 3-, 3- to 6-, 6- to 9-, and 9-to 12-inch depths. Particle size distribution, Atter-berg limits,2 and specific gravity of soil particles
1A joint research project of the Pacific Southwest For-est and Range Experiment Station, Forest Service, U.S. Department of Agriculture, and the U.S. Army Corps of Engineers, Waterways Experiment Station, in coopera-tion with the Hawaii Forestry Division and the Hawaiian Sugar Planters Association.
2Atterberg limits or consistency limits are the bound-aries determined by moisture content (percent by weight) at which a soil may exist in different states: (a) Liquid limit--the boundary between liquid and plastic states; (b) plastic limit--the boundary between the plastic and semi-solid states; and (c) shrinkage limit--the boundary between semi-solid and solid states. Plasticity index is the numerical difference between the liquid limit and plastic limit.
were determined by following standard methods at the U.S. Army Corps of Engineers Waterways Experiment Station, Vicksburg, Miss. The pH of soils was determined by using a standard colori-metric kit.3 Organic matter content of most soils was determined at the Mississippi Agricultural Experiment Station, Starkville, by using a modi-fied Walkley rapid-dichromate method (Peech et al. 1947). Certain samples high in organic matter content were analyzed by the loss-on-ignition method (Association of Official Agricultural Chemists 1945).
Soil moisture retained at 15 atmospheres pres-sure (wilting point) was determined by the pres-sure-membrane method (Richards 1947). Undis-turbed cores in triplicate were obtained to deter-mine bulk density and soil moisture retained at 0 and 0.06 atmosphere tension using the method of Learner and Shaw (1941). Soil moisture re-tained at 60 centimeters water tension was taken as the upper limit of available soil moisture or field capacity.4 Permanent wilting point was taken as the moisture retained at 15 atmospheres pres-sure. Available water capacity was calculated by subtracting the water held at 15 atmospheres pres-sure from the water retained at 60 centimeters tension.
Volume of large pores or readily drained pores was calculated by subtracting the total pore space occupied by water at 0.06 atmosphere tension from the total pore volume (Broadfoot and Burke 1958). The total pore volume was calculated from the average bulk density and average specific grav-ity of the soil particles.
We grouped the data representing known land use conditions into four categories: forest, pas-ture, cultivated area, and idle grassland (table 4, appendix).
The forest category consisted of soils support-ing trees and associated vegetation. Soils in pas-tures were mainly under grasses, but some were under a mixed growth of grass, guava, ferns, and herbaceous cover. Eight of the cultivated soils were under sugar cane; one under pineapple; and
3Truog soil reaction tester by Hellige, Inc. 4Data collected at the Vicksburg Research Center,
Southern Forest Experiment Station, by Broadfoot and Burke (1958) indicated that the 60-centimeter determi-nation closely approximated field capacity for all textural classes of soils in the United States.
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one under a stand of papaya, grass, and guava. Idle grassland areas are those formerly cultivated or used as pasture several years ago but now idle and under grass cover.
Soil Properties
In spite of apparent textures, most soils of Ha-waii fully dispersed are clay to colloidal in particle size (Hough and Byers 1937; Hough et al. 1941; Kelley et al. 1915; Tanada 1951; Richter 1931; Sherman 1955). They are aggregates of clay and colloidal particles and very difficult to disperse. Hough et al. (1941) concluded that conventional methods of analysis were useless, because the soils of Hawaii they studied consisted almost entirely of colloidal material. The hydrometer method is more reliable for dry area soils in which leaching is not a significant factor, according to Wadsworth (1936).
The dominance of colloids strongly affects other soil properties. Fieldes (1955) has shown that dispersion is difficult when pumice soils have allo-phane. Packard (1957) found that the surface
Figure 1.--Classification of soil texture of 34 soil sites studied, 0- to 6-inch depth.
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area method gave 9.6 percent more clay than the mechanical analysis of the same soils. Hough and Byers (1957) found that concretionary or aggre-gate material with a low degree of dispersion accounts for the high permeability and greater distribution of organic matter throughout the soil horizon. During our field investigations of soil strength and moisture characteristics, we found that soil structure was water stable and retains high permeability under wet conditions.
Texture and Structure
The majority of the soils sampled were fine-textured by mechanical analysis (figs. 1 and 2). The 0- to 6-inch layers of 7 out of 11 soils under forest cover were classified in the field as loamy type. Laboratory analysis indicates that three of these soils were of clay texture. Loamy soils are, in general, more favorable for forest growth than coarse sands or fine clays (Lutz and Chandler 1951). Of the 11 grass-covered soils classified in the field, 4 were clay in texture, 3 silty clay loam, and 4 silty clay.
Soil structure is greatly influenced by different land usage. Total pore volume and volume of large pores are highest in soils under forest (table 1 and fig. 3).
Figure 2.--Classification of soil texture of 34 soil sites studied, 6- to 12-inch depth.
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Table 1. Porosity and soil moisture constants ( percent by vol-ume ) of soils, 0- to 12-inch depth, under four different land uses
Total pore volume
Large pore volume
Field capacity
Wilting point
Available moisture
Mean
Stand-arddevia-tion
Mean
Stand-anddevia-tion
Mean
Stand-anddevia-tion
Mean
Stand-anddevia-tion
Mean
Stand-anddevia-tion
Land use
Forest: 11 sites
Pastureland: 6 sites
Cultivated areas: 10 sites
Idle grassland: 7 sites
Pct.
74
71
69
68
Pct.
6
11
8
11
Pct.
18
14
10**
10**
Pct.
7
6
4
6
Pct.
57
56
58
58
Pct.
12
8
9
13
Pct.
28
38***
35***
32
Pct.
7
5
4
5
Pct.
28
19*
24
26
Pct.
10
4
11
12 * Significant at .10 level when compared to forest soils.
** Significant at .95 level when compared to forest soils. *** Significant at .01 level when compared to forest soils.
Bulk Density
Low volume weight signifies relative porous soil condition and high values indicate greater compactness, lowered field capacity, and lower infiltration rates.
Except for some ash soils of Hawaii, analysis of the limited data indicates that bulk density tends to decrease with increased rainfall. Soils under low rainfall may have moderately low bulk density, but no soils under high rainfall have high density. Wadsworth (1936) also reported that soil bulk density decreased as rainfall increased.
Forest soils had the lowest average bulk density (table 2). Pasture and cultivated soils as expected had higher average bulk densities, although un-grazed grassland soils had the highest average value. Trouse and Humbert (1960) reported that some soils of Hawaii will compact and puddle
Figure 3.-Soil moisture constants (percent by volume, 0- to 12-inch depth) related to vegetative cover.
Table 2. Properties of soils under four different land uses, 9- to 12-inch depth
Land use
pH cific gravity Organic matter Bulk density
Mean Stand-and devia-tion
MeanStand-anddevia-tion
MeanStand-anddevia-tion
MeanStand-anddevia-tion
Spe
Forest: Pct. Pct. Pct. Pct. Pct. Pct.
11 sites --------------Pastureland:
6 sites---------------Cultivated areas:
10 sites --------------Idle grassland:
7 sites---------------
6.2
5.9
6.2
7.0
3.3
0.4
1.3
1.3
2.94
2.75
2.82
2.91
0.34
0.18
0.26
0.16
6.5
8.7
5.0
5.1
3.0
8.7
5.0
4.2
0.76
0.81
0.88
0.93
0.22
0.34
0.26
0.36
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Figure 4.-Classification of surface (0-6 inches) soils by the Casagrande plasticity chart, showing that most points in the soils of Hawaii that were studied fell be-low the arbitrarily set "A" line, and beyond the 50 percent moisture content line.
drastically with traffic. The resulting increase in bulk density reduced soil moisture. The reduction of soil moisture with increase in bulk density was significant for the Hydrol Humic Latosols in which water is not held in the interstices of the soil par-ticles. In other soils, the increase in bulk density significantly lowered porosity, but increased the water held at field capacity.
Soil Consistency
Ash-formed soils on the island of Hawaii have the highest plastic limits, the wet area soils of Kauai and Oahu have intermediate values, and the dry area soils on the three islands generally have lower values of plastic limit.
Soils should not be disturbed at or beyond their plastic limit because puddling occurs at these mois-ture contents. Plasticity is not as important in forest soils as in agricultural soils under intense cultivation. Nevertheless forest soils, if highly plas-tic, can be damaged by disturbance during wet periods. Soils disturbed at or beyond their liquid
imit will behave as a liquid.5 Data on soil con-sistency (table 3) can be used as a guide to tillage as well as to logging practices.
The liquid limit and the plasticity index of the surface (0 to 6 inches) soils were plotted on the Casagrande plasticity chart6 by extending the range of plasticity index and liquid limit. Most soils were in the MH class (fig. 4). "C" represents clay soils, "M" silty soils, and "O" organic soils. "L" represents liquid limits below 50, and "H" above 50. The "A" line represents the empirical bound-ary between the various plasticity groups. "MH", therefore, means that the soil material behaves as though it was predominantly silty with liquid limit above 50.
The Dark Magnesium Clay soil and one of the Alluvial soils have the lowest plastic limits at the 0- to 6-inch depth. These soils should not be dis-
5For trafficability, the liquid and plastic limits of the 6- to 12-inch layer are critical (Carlson and Horton 1957).
6U.S. Army Corps of Engineers Waterways Experiment Station. The unified soil classification system. Tech. Memo. 3-357, 30 pp., illus. 1953.
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turbed when the moisture content exceeds their plastic limit (25 percent by dry weight). The highest plastic limit (117 percent) was found in the Latosolic Brown Forest soil. This soil would not be easily compacted except at very high moist-ture contents, above 117 percent moisture (by dry weight).
Organic Matter, pH, Specific Gravity
Pasture and forest soils had the highest average organic matter contents. The average pH for soils
under all types of land use ranged from medium acid to neutral (table 2). The greater range in pH of forest soils indicates a greater range of rain-fall and elevation between sampling sites. Kanehiro et al. (1951) reported that soils of the dry lowland areas tend to increase in acidity during hot sum-mer months, but upland soils showed no increase in pH during summer months. There are no pro-nounced seasonal leaf falls, and the contribution of basic ions from leaves may not be significant.
The specific gravity of soil particles averaged 2.86, which is in contrast to the low bulk densities of some soils (table 2).
Table 3. Atterberg limits of selected soils in Hawaii
Great Site 0- to 6-inch layer 6- to 12-inch layer
soil number Liquid Plastic Plasticity Liquid Plastic Plasticity
group limit limit index limit limit index
Percent by dry weight
Percent by dry weight
Alluvial--------------------- 1 66 34 32 68 34 34 4 94 45 49 85 41 44
188 53 25 28 52 23 29 Dark Magnesium
Clay ------------------------ 189 25 45 72 25 47
Gray Hydromorphic------ 5 89 38 51 96 39 57 13 38 54 108 41 67
Humic Ferruginous Latosol 14 42 4 50 38 12
186 59 36 23 2 38 24 187 53 30 23 66 32 34 198 92 54 38 110 57 53 199 88 49 39 81 45 36
Humic Latosol ----------- 8 128 86 42 213 142 71 9 116 82 34 143 112 31
15 88 60 28 89 64 25 16 54 36 18 55 32 23
191 114 57 57 112 57 55 192 129 61 68 104 55 49 193 153 86 67 133 76 57 194 116 73 43 101 65 36 201 114 84 30 136 98 38
Hydrol Humic Latosol 6 3 87 144 109 35
195 183 103 80 251 172 79 196 254 102 152 8 193 135 197 125 98 27 160 101 59
Latosolic Brown Forest ------------------- 7 137 117 20 222 1 41
12 90 89 1 0 101 9 200 102 68 34 141 80 61
Low Humic Latosol-- 2 32 36 71 32 39 3 65 32 33 66 33 33
184 77 42 35 69 43 26 185 62 35 27 64 38 26 190 53 34 19 64 38 26
Reddish Brown --------- 11 68 37 31 68 41 27
Reddish Prairie---------- 10 9 80 29 130 118 12
70
92
46 6
11 26
32
1811
68
10
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Soil Moisture Constants and Land Use
Soil moisture constants, total pore volume, and aeration of soils were compared under the four categories: forest, pasture, cultivated area, and idle grassland (fig. 3 and table 1).
The data indicate that average total pore volume was highest under forest cover, but the difference with the other categories were not statistically significant (table 1) .
Infiltration rates were not measured, but forest soils probably have a greater infiltration capacity7
as indicated by average higher total pore volume and large pore volume. By the same assumption pasture soils have a higher infiltration capacity than cultivated or idle land soils. These differences may indicate that some pastures are not heavily grazed. Also, inherent properties of the soil as well as land use influence infiltration capacity.
No significant difference in field capacity among the four categories of land use was found.
Average available moisture was highest in the forest soils and lowest in the pasture soils. The difference of 9 percent between the forest and pasture is significant at the 10 percent level. No significant differences in average available mois-ture existed between forest and cultivated soils or between forest and idle grassland soils.
The average volume of large pores was highest in the forested soils and lowest in the cultivated and idle grassland soils. The differences compared to forest soils are statistically significant.
The average wilting point was lowest for soils under forest, higher for idle grassland and culti-vated land, and highest under pastures. The differ-ence in wilting point of 10 percent moisture (by volume) between forest and pasture and a differ-ence of 7 percent moisture (by volume) between forest and cultivated soils were highly significant at the 1 percent level (table 1).
Individual differences in total pore space, avail-able water, unavailable water, large pores, and wilting point are shown in figure 3 and table 5 (appendix).
Total pore volume is generally lower for Low Humic Latosols and Alluvial soils and highest in Hydrol Humic Latosols. Available moisture ca-
7The maximum rate at which water can enter the soil surface (Lassen et al. 1952).
pacity is higher under Hydrol Humic Latosols and some Latosolic Brown Forest soils. The volume of large pores is lower for Hydrol Humic Latosols, Alluvial, Gray Hydromorphic, and Dark Mag-nesium Clay soils. Eleven soils had a wilting point of greater than 30 percent moisture (by volume) of which 7 were under forest cover, 1 under culti-vation and 3 in idle grassland. Soils with higher wilting points (40 percent by volume) are the Gray Hydromorphics and some of the Humic Latosols.
Summary
• Most surface soils in Hawaii are fine textured and composed of aggregates of clay and colloidal particles. Data show that forest soils have struc-tures which favor infiltration and percolation of water.
• Forest soils were found to have the lowest average bulk density; pasture and cultivated soils, as expected, have higher bulk densities. Except for some of the ash soils of Hawaii, bulk density tended to decrease as rainfall increased.
• Soils studied on the island of Hawaii have the highest plastic limits, the wet area soils of Kauai and Oahu have intermediate values, and the dry area soils on the three islands have lower values of plastic limit. The majority of the soils have liquid limits above 50 and therefore should behave like a silty soil or clay soil relatively high in or-ganic matter.
• Pasture and forest soils have the highest aver-age organic matter content.
• The specific gravity of soil particles of all soils sampled averaged 2.86.
• Average total pore volume is highest under forest cover, although the difference from other categories was not statistically significant.
• The average volume of large pores is highest in the forest soils and lowest in the cultivated and idle grassland soils.
• Average field capacity is about the same under each of the four land use categories.
• Average available moisture is highest in the forest soils and lowest in the pasture soils.
• The average wilting point of the soil is lowest under forest and highest under pasture.
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Literature Cited
Association of Official Agricultural Chemists. 1945. Official and tentative methods of analysis of the association. Ed. 6. 932 pp.,
illus. Washington, D. C. Broadfoot, W. M., and Burke, H. D.
1958. Soil moisture constants and their variation. U.S. Forest Serv. South-ern Forest Expt. Sta. Occas. Paper 166, 27 pp., illus.
Carlson, C. A., and Horton, J. S. 1957. Forecasting trafficability of soils; information for predicting moisture
in the surface foot of soils, U.S. Army Corps Engin. Waterways Expt. Sta. Tech. Memo 3-331, Rpt. 4, 26 pp., illus.
Fieldes, M. 1955. Clay mineralogy of New Zealand soils. Part II: Allophane and re-
lated mineral colloids. New Zealand Jour. Sci. Technol. Bul. 37:336-350, illus.
Hough, G. J., and Byers, H. G. 1937. Chemical and physical studies of certain Hawaiian soil profiles. U.S.
Dept. Agr. Technol. Bul. 584, 26 pp., illus. Hough, G. J., Gile, P. L., and Foster, Z. C.
1941. Rock weathering and soil profile development in the Hawaiian Islands. U.S. Dept. Agr. Tech. Bul. 752, 43 pp.
Kanehiro, K., Matsusaka, Y., and Sherman, Donald G. 1951. The seasonal variation in pH of Hawaiian soils. Univ. Hawaii Agr.
Expt. Sta. Tech. Bul. 14, 19 pp., illus. Kelley, W. P., McGeorge, W., and Thompson, R.
1915. The soils of the Hawaiian Islands. Hawaii Agr. Expt. Sta. Bul. 40, 35 pp.
Lassen, L., Lull, W. H., and Frank, B. 1952. Some plant-soil water relations in watershed management. U.S. Dept.
Agr. Cir. 910, 64 pp., illus. Learner, R. W., and Shaw, B.
1941. A simple apparatus for measuring non-capillary porosity on an extensive scale. Jour. Amer. Soc. Agron. 33:1003-1008, illus.
Lutz, Harold J., and Chandler, Robert F. 1951. Forest soils. 514 pp., illus. New York: John Wiley & Sons, Inc.
Packard, R. G. 1957. Some physical properties of Taupo pumice soils of New Zealand.
Soil Sci. 83:273-289, illus. Peech, M., Alexander, L. T., Dean, L. A., and Reed, F. A.
1947. Methods of soil analysis for soil fertility investigations. U.S. Dept. Agr. Cir. 757, 25 pp.
Richards, L. A. 1947. Pressure-membrane apparatus-construction and use. Agr. Engin.
28:451-454, illus. Richter, C.
1931. Physical properties of Hawaii soils with special reference to the colloidal fraction. Hawaii Agr. Expt. Sta. Bul. 62, 45 pp., illus.
Sherman, Donald G. 1955. Chemical and physical properties of Hawaiian soils; soil survey of
Hawaii. U.S. Dept. Agr. Soil Survey Series 1939(25):110-124.
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Tanada, T. 1951. Some of the properties of Hawaiian soil colloids. Jour. Soil Sci.
2:85-96, illus. Trouse, A. C., and Humbert, R. P.
1960. Some effects of soil compaction on the development of sugar cane roots. Soil Sci. 91(3) :208-217, illus.
U.S. Army Corps of Engineers Waterways Experiment Station. 1951. Soils laboratory manual, Lower Mississippi Valley division. 47 pp.,
illus. Wadsworth, Harold A.
1936. Physical aspects. Handbook of Hawaiian soils. pp. 147-173, illus. Honolulu: Assoc. Hawaiian Sugar Technologists.
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Appendix
Table 4. Description of soils and sampling sites, by land use
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Table 5. Properties of selected soils in Hawaii, by great soil group
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